阴离子交换膜辅助电解还原法处理含镉废水：原理及优化

王维猛; 武卫兵; 冯季军

doi:10.7524/j.issn.0254-6108.2021080701

阴离子交换膜辅助电解还原法处理含镉废水：原理及优化

1.
济南大学材料科学与工程学院，济南，250022
2.
济南大学化学化工学院，济南，250022

通讯作者: E-mail：mse_wuwb@ujn.edu.cn;; chem_fengjj@ujn.edu.cn

基金项目:
山东省自然科学基金 ( ZR2019MEM033)资助

Anion exchange membrane-assisting electrochemical reduction treatment on Cd-containing wastewater: Principle and optimization

1.
School of Material Science and Engineering, University of Jinan, Jinan, 250022, China
2.
School of Chemistry and Chemical Engineering, University of Jinan, Jinan, 250022, China

Corresponding authors: WU Weibing, mse_wuwb@ujn.edu.cn ; FENG Jijun, chem_fengjj@ujn.edu.cn

Fund Project: the Natural Science Foundation of Shandong ( ZR2019MEM033)

摘要: 本文研究了阴离子交换膜（AEM）辅助电解还原法处理含镉废水．通过对比电解还原过程中是否采用AEM膜对溶液pH、电解电压、除镉率和能耗变化的影响，阐明电解还原法除镉的化学原理，找出限制除镉效率的原因，提出了优化方案．研究发现，H⁺的扩散是除镉效率的主要限制因素，研究中进一步采用阴离子交换膜，利用其对离子的选择透过性，限制了阳极室生成的H⁺向阴极室的扩散，抑制了含镉废液pH的下降，减弱了析氢效应及对电解生成金属镉的酸腐蚀，明显提高了电解还原除镉的效率．废液中Cd²⁺浓度从33.6 g·L⁻¹降低到1.06 mg·L⁻¹，镉去除率达99.99%，电荷效率98%，消耗电能为270 Wh·L⁻¹．
- 镉废水处理 /
- 电解还原法 /
- 阴离子交换膜 /
- 电化学原理
Abstract: This article studies the treatment on cadmium-containing wastewater by anion exchange membrane (AEM)-assisting electrolytic reduction. By comparing the influence of AEM membrane on the changing trends of the solution pH, voltage, cadmium removal rate and energy consumption during the electrolysis, the chemical principle for the electrolysis was revealed,the reasons of limiting cadmium removal efficiency were found, the electrolysis reduction process was optimized. The research found that the diffusion of H⁺ is the main limiting factor for the cadmium removal efficiency. In the research, the anion exchange membrane was further used, by utilizing its selective permeability to ions to limit the diffusion of H⁺ generated in the anode compartment to the cathode compartment. The reduction of pH of cadmium waste liquid was inhibited, the hydrogen evolution reaction and acid etching of the electrolytic metal cadmium were weakened, significantly improve the efficiency of electrolytic reduction to remove cadmium. The residual Cd²⁺ concentration after treatment is reduced from 200 mg·L⁻¹ to 1.06 mg·L⁻¹, the cadmium removal rate reaches to 99.99%, the charge efficiency 98%, and the power consumption is 270 Wh·L⁻¹.
- cadmium wastewater treatment /
- electrochemical reduction /
- anion exchange membrane /
- electrochemistry principle
图 1 电解除镉实验装置示意图

Figure 1. Schematic diagram of the experimental device for electrolytic removing cadmium

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图 2 不同基底在含镉和无镉溶液中的线性扫描伏安曲线

Figure 2. Linear scanning voltammetry plots of Cd-free and containing solutions on different substrates

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图 3 阴离子交换膜结构及离子导电性能

Figure 3. Structure and ionic conductivity of anion exchange membrane

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图 4 无膜电解还原除镉时溶液pH和电解电压的变化

Figure 4. pH and voltage trends during electrolysis treatment without membrane

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图 5 阴极表面电解还原析出的金属镉的SEM照片

Figure 5. SEM images of electrolysis reduced Cd metal on the surface of cathode: (a) full view, (b) magnified view of the dense area, (c) magnified view of dendritic end

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图 6 膜电解还原除镉过程中pH和电压变化

Figure 6. pH and voltage trends during electrolysis treatment with membrane

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图 7 阴离子膜参与的电解还原除镉原理图

Figure 7. Principle diagram of electrolytic reduction for removing cadmium with anion membrane

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图 8 (a) 不同电流密度下pH随电解时间的变化，(b)去除率和最终溶液Cd²⁺浓度的变化电流密度分别为0.01、0.02、0.04、0.008 A·cm⁻²

Figure 8. (a) pH changes with electrolyzation time under different current densities, (b) cadmium removal rate and final Cd²⁺ concentration in solution at varied current density of 0.01, 0.02, 0.04, 0.008 A·cm⁻²

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图 9 无膜和有膜电镀法除镉的去除率及能耗对比图

Figure 9. Comparison of the removal rate and energy consumption of cadmium removal by electrolysis with and without membrane

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工业上，镉常用于对内层金属的防护^[1]，比如海洋环境下金属制品的防腐保护和飞机降落架上固件的电镀^[2]，然而制备镉镀件的电镀液常常含有浓度高达40—50 g·L⁻¹的氯化镉或40—60 g·L⁻¹的硫酸镉^[3]. 近年来，太阳能光伏电池发展迅速，CdTe薄膜光伏电池也得以大规模应用，明显扩大了镉的应用规模^[4]. 无论是电镀法生产CdTe薄膜还是未来CdTe薄膜电池的回收再利用，都会涉及大量含镉废水的处理，比如CdTe薄膜的电镀液中CdSO₄的浓度达0.3 mol·L⁻¹（33.6 g·L⁻¹），废弃CdTe薄膜电池的回收通常采用酸溶解CdTe形成高浓度含镉溶液^[5-6]. 这些都无疑会成为工业上含镉废水排放与控制的重大难题. 镉的危害主要体现在容易通过水体富集经食物链进入人体，导致肾损害与软骨病^[7]. 近年来，随着世界尤其是我国对环境保护和整治的重视，镉被列为实施排放总量控制的重点监控指标之一，我国《污水综合排放标准》（GB8978—1996）明文规定工业废水中镉的最高允许排放浓度为0.1 mg·L⁻¹.

针对镉废液的处理，工业上已发展了化学沉淀法、铁氧体法、电絮凝法、吸附法和离子交换法等多种方法. 化学沉淀法是工业上最常用的，一般先形成Cd(OH)₂、CdS、Cd₃(PO₄)₂等难溶物，再通过凝聚、沉降、浮选、过滤、吸附等过程将沉淀从溶液中分离，镉去除率仅98%左右，并且产生大量固体污泥，易造成二次污染^[8-9]. 铁氧体法通过铁氧体与镉共沉淀，去除率达到99%，但该方法需不断通空气氧化，能耗高^[10-11]. 吸附法和离子交换法主要适用于处理低浓度镉废液，但存在吸附剂再生和工艺条件确定困难，稳定性差和成本高的问题^[12-14]. 近年来，随着技术进步，电化学法逐渐被用于含镉废液处理. 比如，电絮凝法解决了絮状沉淀较分散，难沉降的问题^[15-18]；电渗析技术通过浓缩减少了废液量，为后续高效处理奠定基础^[19], 电渗析、反渗透、纳滤等常规脱盐膜技术的发展同时扩大了膜技术在废水处理领域的应用^[20]. 相比而言，将金属离子去除与金属回收相结合，发展直接从废水中提取纯金属的技术更有意义，电解还原法为此提供了可能^{[21- 22]}. 比如，选择特定几何形状和高比表面积的材料^[23-24]或者在40 V左右的高电压下^[25]通过电化学还原处理低浓度废液，Cd²⁺去除率达到99%. 考虑到电解还原速率与溶液中金属离子浓度相关，低浓度下受Cd²⁺扩散控制，电解法将更适合处理高浓度含镉废液. 然而，在高浓度下，随着阳极析氧和阴极析出金属镉，溶液pH会不断下降，不但会增加后期电解还原时的析氢电流，还会酸性腐蚀析出的金属镉，继续降低残留镉浓度困难很大. 可见，为提高电化学还原法处理镉废液的能力，需要减缓阴极侧溶液pH的下降幅度、提升pH的最低值. 阴离子交换膜（anion exchange membrane, AEM）是一种对阴离子选择性透过而对阳离子有阻挡作用的高分子膜^[26]. 在电解还原过程中，引入AEM膜分隔阴极和阳极来阻止阳极生成的H⁺向阴极扩散，可达到防止阴极溶液pH过度下降的目的. 然而，报道发现^[3]，采用AEM膜仅可将Cd²⁺浓度降低到90 mg·L⁻¹，去除率92.9%，远未达到排放标准.

本文通过对比研究AEM膜在电解还原处理高浓度含镉废水中的作用，阐明过程的化学原理，确定制约含镉废水处理效果的问题原因，进而提出优化方案. 研究发现，通过控制电解还原电流和阴极溶液pH值来维持Cd²⁺的还原活性和减少析氢量，可以将Cd²⁺残留浓度从优化前的200 mg·L⁻¹降低到1.06 mg·L⁻¹，去除率达到99.99%. 本研究为未来继续提升电解还原含镉废水的处理效果并最终达到排放指标明确了研究方向.

3. 结论（Conclusion）

（1）对比研究了AEM在电解还原处理高浓度（33.6 g·L⁻¹）模拟镉废液过程中溶液pH和电解电压的变化，发现阳极析氧产生H⁺和Cd²⁺水解对pH的缓冲作用引起的氢气共析和金属镉酸腐蚀是制约镉废水处理效率和残留Cd²⁺浓度高的关键.

（2）引入AEM膜可有效阻止H⁺向阴极扩散，减少析氢速率和金属镉的酸腐蚀，但是高电流密度下析氢会导致阴极pH上升过快，除镉过程提前终止，效率下降.

（3）进一步优化AEM膜参与的电解还原除镉实验，将电流降低到仪器最低值0.04 A和并控制溶液pH=2.0左右，明显减缓了阴极溶液pH的上升，延长了有效电解还原除镉的时间，将残留Cd²⁺浓度从优化前的200 mg·L⁻¹降低到1.06 mg·L⁻¹，Cd²⁺去除率达99.99%，电荷效率98%，能耗270 Wh·L⁻¹.

（4）高浓度镉废液的电解还原工艺和电解系统仍有较大提升空间，选择对Cd²⁺强吸附的阴极材料，增大电解电压，缩短阴极与膜间距，提高电极面积与溶液体积比等多种途径都可继续提高镉废液的处理效率，研究结论为未来电解还原工艺的继续优化指明了方向.

参考文献 (27)

阴离子交换膜辅助电解还原法处理含镉废水：原理及优化

通讯作者: E-mail：mse_wuwb@ujn.edu.cn;; chem_fengjj@ujn.edu.cn

Anion exchange membrane-assisting electrochemical reduction treatment on Cd-containing wastewater: Principle and optimization

Corresponding authors: WU Weibing, mse_wuwb@ujn.edu.cn ; FENG Jijun, chem_fengjj@ujn.edu.cn

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阴离子交换膜辅助电解还原法处理含镉废水：原理及优化

通讯作者: E-mail：mse_wuwb@ujn.edu.cn;; chem_fengjj@ujn.edu.cn

English Abstract

Anion exchange membrane-assisting electrochemical reduction treatment on Cd-containing wastewater: Principle and optimization

Corresponding author: WU Weibing, mse_wuwb@ujn.edu.cn ;

Corresponding authors: FENG Jijun, chem_fengjj@ujn.edu.cn

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1.1. 实验材料和仪器

1.2. 实验过程

1.3. 电解实验原理

2.1. 阴离子交换膜性能

2.2. 无AEM膜的电解还原

2.3. 有AEM膜的电解还原

2.4. AEM膜参与的电解还原除镉原理

2.5. 阴离子交换膜电解还原除镉的工艺优化

2.6. 无膜和有膜电解还原除镉能耗和效果分析

目录

阴离子交换膜辅助电解还原法处理含镉废水：原理及优化

通讯作者: E-mail：mse_wuwb@ujn.edu.cn;; chem_fengjj@ujn.edu.cn

Anion exchange membrane-assisting electrochemical reduction treatment on Cd-containing wastewater: Principle and optimization

Corresponding authors: WU Weibing, mse_wuwb@ujn.edu.cn ; FENG Jijun, chem_fengjj@ujn.edu.cn

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阴离子交换膜辅助电解还原法处理含镉废水：原理及优化

通讯作者: E-mail：mse_wuwb@ujn.edu.cn;; chem_fengjj@ujn.edu.cn

English Abstract

Anion exchange membrane-assisting electrochemical reduction treatment on Cd-containing wastewater: Principle and optimization

Corresponding author: WU Weibing, mse_wuwb@ujn.edu.cn ;

Corresponding authors: FENG Jijun, chem_fengjj@ujn.edu.cn

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1.1. 实验材料和仪器

1.2. 实验过程

1.3. 电解实验原理

2.1. 阴离子交换膜性能

2.2. 无AEM膜的电解还原

2.3. 有AEM膜的电解还原

2.4. AEM膜参与的电解还原除镉原理

2.5. 阴离子交换膜电解还原除镉的工艺优化

2.6. 无膜和有膜电解还原除镉能耗和效果分析

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